2,412 research outputs found
Stresses in the vicinity of an un-reinforced mitre intersection: an experimental and finite element comparison
The experimental investigation reported provides elastic stresses in the vicinity of the unreinforced intersection of a single 90° mitred bend, subjected to an in-plane bending moment. The specimen was extensively strain gauged on the outer surface. A small number of rosettes were also laid on the inside surface close to the welded intersection. The procedures used for the successful installation of the inside surface gauges are discussed. In the experiment, consideration was also given to deflections and rotations. Satisfactory comparisons with adaptive-p thin-shell finite element results were obtained in general and differences are explained in terms of the known experimental variables and finite element approximations. The nature of the stresses at such intersections is discussed and various methods of obtaining fatigue 'hot-spot' stresses are considered
Using molecular similarity to construct accurate semiempirical electron structure theories
Ab initio electronic structure methods give accurate results for small
systems, but do not scale well to large systems. Chemical insight tells us that
molecular functional groups will behave approximately the same way in all
molecules, large or small. This molecular similarity is exploited in
semiempirical methods, which couple simple electronic structure theories with
parameters for the transferable characteristics of functional groups. We propse
that high-level calculations on small molecules provide a rich source of
parametrization data. In principle, we can select a functional group, generate
a large amount of ab initio data on the group in various small-molecule
environments, and "mine" this data to build a sophisticated model for the
group's behavior in large molecules. This work details such a model for
electron correlation: a semiempirical, subsystem-based correlation functional
that predicts a subsystem's two-electron density as a functional of its
one-electron density. This model is demonstrated on two small systems: chains
of linear, minimal-basis (H-H)5, treated as a sum of four overlapping (H-H)2
subsystems; and the aldehyde group of a set of HOC-R molecules. The results
provide an initial demonstration of the feasibility of this approach.Comment: The following article appeared in the Journal of Chemical Physics,
121 (12), 5635-5645 (2004) and may be found at http://jcp.aip.org
Magnetic molecules created by hydrogenation of Polycyclic Aromatic Hydrocarbons
Present routes to produce magnetic organic-based materials adopt a common
strategy: the use of magnetic species (atoms, polyradicals, etc.) as building
blocks. We explore an alternative approach which consists of selective
hydrogenation of Polycyclic Aromatic Hydrocarbons. Self-Consistent-Field (SCF)
(Hartree-Fock and DFT) and multi-configurational (CISD and MCSCF) calculations
on coronene and corannulene, both hexa-hydrogenated, show that the formation of
stable high spin species is possible. The spin of the ground states is
discussed in terms of the Hund rule and Lieb's theorem for bipartite lattices
(alternant hydrocarbons in this case). This proposal opens a new door to
magnetism in the organic world.Comment: 6 pages, 4 figures and 2 table
A simplified picture for Pi electrons in conjugated polymers : from PPP Hamiltonian to an effective molecular crystal approach
An excitonic method proper to study conjugated oligomers and polymers is
described and its applicability tested on the ground state and first excited
states of trans-polyacetylene, taken as a model. From the Pariser-Parr-Pople
Hamiltonian, we derive an effective Hamiltonian based on a local description of
the polymer in term of monomers; the relevant electronic configurations are
build on a small number of pertinent local excitations. The intuitive and
simple microscopic physical picture given by our model supplement recent
results, such as the Rice and Garstein ones. Depending of the parameters, the
linear absorption appears dominated by an intense excitonic peak.Comment: 41 Pages, 6 postscript figure
Optical Absorption Study by Ab initio Downfolding Approach: Application to GaAs
We examine whether essence and quantitative aspects of electronic excitation
spectra are correctly captured by an effective low-energy model constructed
from an {\em ab initio} downfolding scheme. A global electronic structure is
first calculated by {\em ab initio} density-functional calculations with the
generalized gradient approximation. With the help of constrained density
functional theory, the low-energy effective Hamiltonian for bands near the
Fermi level is constructed by the downfolding procedure in the basis of
maximally localized Wannier functions. The excited states of this low-energy
effective Hamiltonian ascribed to an extended Hubbard model are calculated by
using a low-energy solver. As the solver, we employ the Hartree-Fock
approximation supplemented by the single-excitation configuration-interaction
method considering electron-hole interactions. The present three-stage method
is applied to GaAs, where eight bands are retained in the effective model after
the downfolding. The resulting spectra well reproduce the experimental results,
indicating that our downfolding scheme offers a satisfactory framework of the
electronic structure calculation, particularly for the excitations and dynamics
as well as for the ground state.Comment: 14 pages, 6 figures, and 1 tabl
Population dynamics of house mice in Queensland grain-growing areas
Context. Irregular plagues of house mice cause high production losses in grain crops in Australia. If plagues can be forecast through broad-scale monitoring or model-based prediction, then mice can be proactively controlled by poison baiting.
Aims. To predict mouse plagues in grain crops in Queensland and assess the value of broad-scale monitoring.
Methods. Regular trapping of mice at the same sites on the Darling Downs in southern Queensland has been undertaken
since 1974. This provides an index of abundance over time that can be related to rainfall, crop yield, winter temperature and past mouse abundance. Other sites have been trapped over a shorter time period elsewhere on the Darling Downs and in central Queensland, allowing a comparison of mouse population dynamics and cross-validation of models predicting mouse abundance.
Key results. On the regularly trapped 32-km transect on the Darling Downs, damaging mouse densities occur in 50% of
years and a plague in 25% of years, with no detectable increase in mean monthly mouse abundance over the past 35 years. High mouse abundance on this transect is not consistently matched by high abundance in the broader area. Annual maximum mouse abundance in autumn–winter can be predicted (R2 = 57%) from spring mouse abundance and autumn–winter rainfall in the previous year. In central Queensland, mouse dynamics contrast with those on the Darling Downs and lack the distinct annual cycle, with peak abundance occurring in any month outside early spring.Onaverage, damaging mouse densities occur
in 1 in 3 years and a plague occurs in 1 in 7 years. The dynamics of mouse populations on two transects ~70 km apart were rarely synchronous. Autumn–winter rainfall can indicate mouse abundance in some seasons (R2 = ~52%).
Conclusion. Early warning of mouse plague formation in Queensland grain crops from regional models should trigger
farm-based monitoring. This can be incorporated with rainfall into a simple model predicting future abundance that will determine any need for mouse control.
Implications. A model-based warning of a possible mouse plague can highlight the need for local monitoring of mouse
activity, which in turn could trigger poison baiting to prevent further mouse build-up
Do harvest refuges buffer kangaroos against evolutionary responses to selective harvesting?
There is a wealth of literature documenting a directional change of body size in heavily harvested populations. Most of this work concentrates on aquatic systems, but terrestrial populations are equally at risk. This paper explores the capacity of harvest refuges to counteract potential effects of size-selective harvesting on the allele frequency,of populations. We constructed a stochastic, individual-based model parameterized with data on red kangaroos. Because we do not know which part of individual growth would change in the course of natural selection, we explored the effects of two alternative models of individual growth in which alleles affect either the growth rate or the maximum size. The model results show that size-selective harvesting can result in significantly smaller kangaroos for a given age when the entire population is subject to harvesting. In contrast, in scenarios that include dispersal from harvest refuges, the initial allele frequency remains virtually unchanged
Ab initio equilibrium constants for H2O–H2O and H2O–CO2
Ab initio 6‐31G** electronic structure calculations have been used to determine the minimum energy geometries and vibrational frequencies of molecular clusters of water and carbon dioxide. Application of statistical thermodynamics leads to theoretical equilibrium constants for gas phase dimerization of water and the formation of an adduct of carbon dioxide with water.The low energy vibrations of the clusters lead to much larger contributions to the vibrational partitioning of the energy than do the fundamental vibrations of the monomeric species. A new ‘‘Harmonic‐Morse’’ formula is derived to estimate anharmonicity from optimized harmonic frequencies and two additional values on the potential surface for each vibration. These ab initiocalculations of equilibrium constants are very close to recent measurements and fall within the range of values obtained by other methods. This no‐parameter treatment gives excellent agreement for the equilibrium of H2O–CO2 near the supercritical fluid range of CO2 and suggests that a ‘‘Theory of Significant Clusters’’ may be extended to a model of supercritical fluids which includes the effects of anharmonicity
On the Structure and Stability of Geometrical Isomers of N3F
The potential energy surfaces for the N3F molecule have been studied using multiconfigurational wave functions. Two new isomers were found, one on the singlet (1 A′) and one on the triplet (3 A″) surface. Both isomers have a three‐membered cyclic structure and C ssymmetry. The singlet cyclic isomer is endoergic relative to the open fluorine azide by 15–17 kcal/mol. Its kinetic stability is close to the stability of the open isomer: the barrier separating the cyclic isomer from the dissociation products N2(X 1Σ+ g )+NF(a 1Δ) is about 13–17 kcal/mol and is lower than the barrier to isomerization. The triplet cyclic isomer is much higher in energy (about 70 kcal/mol), with a barrier to dissociation to N2(X 1Σ+ g )+NF(X 3Σ−) on the order of 15 kcal/mol. Crossings of the 1 A′ and the 3 A″ surfaces may allow the cyclic singlet isomer to predissociate to the ground state products, N2(X 1Σ+ g )+NF(X 3Σ−). It is shown, however, that the singlet–triplet surface of intersection lies ‘behind’ the barrier to singlet decomposition, so that spin‐forbidden predissociation will not preclude detection of cyclic N3F
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